JP6341992B2 - Communication apparatus and method - Google Patents

Description

  The present invention relates to a method and apparatus for use in a wireless (mobile) communication system. In particular, embodiments of the present invention relate to a method and apparatus for providing coverage enhancement in a wireless communication system.

  Third and fourth generation mobile communication systems, such as mobile communication systems based on 3GPP defined UMTS and Long Term Evolution (LTE) architectures, are more than simple voice and messaging services provided by previous generation mobile communication systems. In addition, it has become possible to support high performance communication services for personal computing and communication devices. For example, with the improved air interface and extended data rate provided by the LTE system, users can use mobile video streaming and mobile video conferencing that were previously only available over fixed line data connections, etc. Of high data rate applications. Therefore, there is a strong demand for deploying third and fourth generation networks, and a response to expand the coverage available in such communication systems is desired (ie, operating in a limited coverage location). There is a need to provide a more reliable connection to a wireless communication system for a terminal device.

  A typical example of a terminal device with limited coverage is a so-called machine type communication (MTC) device, which is located in the customer's house and relates to the consumption of customers in utilities such as gas, water and electricity. It is like a smart meter that periodically returns information to the central MTC server. For example, such a terminal device may be located in a basement or other location that has a relatively high penetration loss, so such a terminal device may operate in a location with limited coverage.

  In some situations, a terminal device in a particular communication cell provided by the base station in a limited coverage situation may communicate from the base station unless specific measures are taken for the terminal device to receive. May not be received. One simple way to increase coverage in such a situation would be to increase its transmit power for the base station. However, coverage with increased transmission power from the base station is expected to cause correspondingly increased interference in adjacent communication cells. Another approach is for a base station to select a subset of transmission resources (eg, in terms of frequency) that are selected from among the transmission resources of the entire base station and allocated for transmission to a terminal device with limited coverage. It will be centralized / gathering the available transmit power. The increased power in this way can be made available to communicate with terminal devices in “hard to reach” without exceeding the total power of the base station. . Such an approach may be referred to as a power boost. Accordingly, a base station having a power boost function may concentrate available transmission power within a limited subset of transmission resources allocated to terminal devices with limited coverage.

This power boost approach is schematically illustrated in FIGS. 1A and 1B showing an example plot of maximum allowable transmit power P versus frequency f for two modes of operation for base stations in LTE-based wireless communication networks. Is shown in FIG. 1A represents a normal mode of operation where the maximum allowable transmit power is uniform at the P ₀ level over the entire base station operating bandwidth S _BW (eg, 20 MHz). Meanwhile in Figure 1B, the over bandwidth S _BW less bandwidth PB _BW in its normal operating mode, at substantially greater power level than the power P ₀ of the available transmit power of the entire normal operating mode P _PB Fig. 4 illustrates a power boost mode of operation of a base station concentrated on allowed transmissions. The base station is expected to be adapted to switch between normal operating mode and power boost mode, eg, depending on current or expected traffic conditions. In general, the overall transmit power will be widely the same in both modes of operation (ie, the area under the curves in FIGS. 1A and 1B will be the same). As a specific example, one implementation PB _BW of power boost operation mode is about a quarter of the S _BW (e.g., PB _BW = 5 MHz in S _BW = 20 MHz), with about four times P _PB is P ₀ There may be. Thus, in this exemplary embodiment, the transmission resources allocated to the terminal device with limited coverage are four times the power that does not exceed the overall power amount for the base station within the frequency bandwidth P _BW . The base station may transmit. In practice, communication with a specific terminal on a specific subcarrier is performed using less power than the maximum allowed, taking into account the conventional power control mechanism provided in a wireless communication system. May be.

  Therefore, a wireless communication network adapted to provide coverage by power boost in difficult situations can be used by multiple resource elements (REs) that sometimes occupy less than the nominal system bandwidth. It may reconfigure itself to concentrate the possible transmit power. A terminal device with limited coverage may be allocated resources on these power boosted resource elements so that the possibility of using the cell becomes high.

  As is well understood, LTE networks have two radio resource control (RRC) modes for terminal equipment: (i) RRC idle mode (RRC IDLE) and (ii) RRC connection mode (RRC CONNECTED). ). When the terminal device transmits data, the RRC connection mode is required. In the RRC idle mode, the core network (CN) portion of the radio communication system recognizes that the terminal device exists in the network, but does not recognize the radio access network (RAN) portion of the radio communication system. Like conventional ones for LTE type wireless communication networks, the terminal equipment measures reference signal received power (RSRP) / reference signal reception quality (RSRQ) in order to receive system information (SI) and paging messages. Can be performed in a communication cell that can operate and can autonomously decide to camp on one specific cell (eg, depending on the RSRP / RSRQ threshold test and the cell's public mobile network (PLMN) identifier) . A base station that supports communication in each cell according to this approach does not play a role in cell selection for the terminal device in idle mode with respect to the cell selection / reselection process autonomously performed by the terminal device in idle mode. . This is in contrast to the cell change procedure in the RRC connection mode in which the terminal device is under the control of the RAN and the handover process is controlled by the network (with the assistance of the measurement of the terminal device).

  As mentioned above, terminal equipment that can benefit from power boost to operate more reliably in a communication cell generally captures the cell whether the cell's base station supports power boost. Or know when you try to camp on. As a result, for example, by decoding the primary synchronization signal (PSS), secondary synchronization signal (SSS), physical broadcast channel (PBCH), and SI of the cell, the terminal device can save time and power resources for performing the camp-on procedure for the cell. Perform random access procedures using physical random access channel (PRACH) resources to spend and subsequently connect to the cell, but eventually find a cell that does not support power boost, and physical downlink control Communication with a terminal device on a channel such as a channel (PDCCH) and a physical downlink shared channel (PDSCH) cannot be reliably supported.

  Even considering a base station that can support power boost, the above-described power boost approach to extend coverage is always used by the base station to reduce the impact on other terminals operating in the cell. May not be supported. For example, a power boost can be a predetermined time of day or night in a given communication cell, depending on when it is expected that the resources required to successfully support a conventional terminal device operating in the cell will be reduced. May only be supported. In these cases, it may be appropriate for a terminal device in need of power boost to sleep (sleep) until such time that power boost is supported before attempting to acquire the associated cell.

  Therefore, there is a need for a scheme that assists in the process of searching for a base station of a wireless communication system to camp on / connect a terminal device that can benefit from power boost for reliable communication in the wireless communication system It is.

  According to a first aspect of the present invention, a power boost mode of operation in which the base station's available transmit power is concentrated to provide enhanced transmit power within a subset of the base station's available transmit resources. A method of operating a terminal apparatus in a wireless communication system including one or more base stations that support the base station, wherein the one or more base stations support the power boost operation mode in the wireless communication system. Receiving a range indication, and controlling base station acquisition of the wireless communication system in a manner that considers the indicated range, wherein one or more base stations support the power boost mode; A method is provided comprising:

  According to a particular embodiment, the indication of the range in which one or more base stations support the power boost mode of operation is: (i) one or more base stations operate in the power boost mode of operation An indication of whether or not to be configured to have a function; (ii) an indication of time when one or more base stations are configured to use the boost mode of operation; and (iii) the power boost mode of operation An indication of available enhanced transmit power for one or more base stations, (iv) one where the downlink physical channel of the wireless communication system uses the power boost mode of operation. Or one or more instructions selected from a group including instructions transmitted by a plurality of base stations.

  According to a particular embodiment, the step of controlling base station acquisition comprises the indicated range in which one or more base stations support the power boost mode in the wireless communication system. Selecting a base station to acquire from a plurality of available base stations.

  According to a particular embodiment, the step of selecting a base station for acquisition is performed during a cell selection procedure or a cell reselection procedure of the terminal device.

  According to a particular embodiment, the step of controlling the acquisition of a base station is based on the indication of the range in which one or more base stations support the power boost mode of operation within the wireless communication system. Delay acquisition of the base station for a period of time.

  According to a particular embodiment, the method further comprises the terminal device entering a reduced activity mode for a period of time during which acquisition of the base station is delayed.

  According to a particular embodiment, the method further comprises deriving one or more characteristics of signals received from one or more base stations in the wireless communication system, and The step of controlling also considers the one or more derived characteristics.

  According to a particular embodiment, the one or more derived characteristics are a reference signal received power (RSRP) measurement associated with a reference signal transmitted from one or more base stations in the wireless communication system. And / or derived from reference signal received quality (RSRQ) measurements.

  According to a particular embodiment, the indication of the range in which one or more base stations within the wireless communication system supports the power boost mode of operation includes an indication that is specific to an individual base station. .

  According to a particular embodiment, the indication of the range in which one or more base stations support the power boost mode of operation in the wireless communication system is applicable to a plurality of base stations.

  According to a particular embodiment, the step of receiving the indication of the range in which one or more base stations support the power boost mode of operation is performed by the first base station from the first base station. Receiving an indication of the range that supports a power boost mode of operation.

  According to a particular embodiment, the step of receiving the indication of the range in which one or more base stations support the power boost mode of operation further comprises: Receiving an indication of the range that supports the mode.

  According to a particular embodiment, the step of receiving the indication of the range in which one or more base stations support the power boost mode of operation, wherein a second different base station supports the power boost mode of operation. Receiving an indication of said range from the first base station.

  According to a particular embodiment, the first base station is a base station to which the terminal device is connected, and the second base station is a base station to which the terminal device is not connected.

  According to a particular embodiment, the step of controlling acquisition of a base station of the wireless communication system determines whether to disconnect from the first base station and connect to the second base station. Including doing.

  According to a particular embodiment, the indication of the range in which one or more base stations support the power boost mode of operation is in communication received from one or more base stations to which no terminal device is connected. Received by the terminal device.

  According to a particular embodiment, the indication of the range in which one or more base stations support the power boost mode of operation is carried by a base station in the wireless communication system to carry other information Is implicitly conveyed to the terminal device in connection with the transmission of.

  According to a particular embodiment, the step of receiving the indication of the range in which one or more base stations in the wireless communication system support the power boost mode of operation comprises transmitting a broadcast signal to one or more broadcast signals. Receiving from the base station and deriving the indication of the range in which one or more base stations support the power boost mode of operation from the transmission resources used for the broadcast signal.

  According to a particular embodiment, the broadcast signal includes a synchronization signal.

  According to a particular embodiment, the indication of the range in which one or more base stations support the power boost mode of operation is received by the terminal device using an explicit signal.

  According to a particular embodiment, the explicit signal comprises a system information signal received from a base station.

  According to another aspect of the present disclosure, at least some downlink communication is performed using a limited subset of transmission resources selected from within a system frequency band, and the channel bandwidth is narrower than the system frequency band A method for operating a terminal device in a wireless communication system comprising one or more base stations supporting a virtual carrier mode of operation, including a limited bandwidth downlink channel comprising: Wherein the one or more base stations receive an indication of the range that supports the virtual carrier mode of operation, and the indicated range of one or more base stations that support the virtual carrier mode of operation. There is provided a method comprising, in a method of considering, controlling acquisition of a base station of the wireless communication system The

  According to a particular embodiment, the step of receiving the indication of the range in which one or more base stations support the virtual carrier mode of operation, wherein a second different base station supports the virtual carrier mode of operation. Receiving an indication of said range from the first base station.

  According to a particular embodiment, the first base station is a base station to which the terminal device is connected, and the second base station is a base station to which the terminal device is not connected.

  According to a particular embodiment, the indication of the range in which one or more base stations support the virtual carrier mode of operation is received by the terminal device using an explicit signal.

  According to a particular embodiment, the explicit signal comprises a system information signal received from a base station.

  In accordance with another aspect of the present invention, a power boost mode of operation in which the base station's available transmit power is concentrated to provide enhanced transmit power within a subset of the base station's available transmit resources. A terminal device for use in a wireless communication system comprising one or more base stations to be supported, the indication of the range in which the one or more base stations support the power boost operation mode in the wireless communication system A terminal configured to control acquisition of a base station of the wireless communication system in a manner that takes into account the indicated range, wherein one or more base stations support the power boost mode. An apparatus is provided.

  According to another aspect of the present disclosure, at least some downlink communication is performed using a limited subset of transmission resources selected from within a system frequency band, and the channel bandwidth is narrower than the system frequency band A terminal device for use in a wireless communication system comprising one or more base stations supporting a virtual carrier mode of operation, including a limited bandwidth downlink channel having the following: In a method that considers the indicated range, wherein one or more base stations receive the indication of the range that supports the virtual carrier mode of operation, and one or more base stations support the virtual carrier mode of operation. A terminal device configured to control acquisition of a base station of the wireless communication system is provided.

  In accordance with another aspect of the present invention, a power boost mode of operation in which the base station's available transmit power is concentrated to provide enhanced transmit power within a subset of the base station's available transmit resources. A method of operating a base station in a wireless communication system comprising one or more base stations to support, defining a range in which the one or more base stations support the power boost mode of operation, and In order to control the acquisition of the base station of the wireless communication system performed by the terminal device, the terminal device can consider the indication of the range in which one or more base stations support the power boost operation mode. As such, one or more base stations operate within the wireless communication system to indicate the range to support the power boost mode of operation. It is transported to the end device, including a method is provided.

  According to a particular embodiment, the indication of the range in which one or more base stations support the power boost mode of operation is: (i) one or more base stations operate in the power boost mode of operation An indication of whether or not to be configured to have a function; (ii) an indication of time when one or more base stations are configured to use the boost mode of operation; and (iii) the power boost mode of operation An indication of available enhanced transmit power for one or more base stations, (iv) one where the downlink physical channel of the wireless communication system uses the power boost mode of operation. Or one or more instructions selected from a group including instructions transmitted by a plurality of base stations.

  According to a particular embodiment, when controlling base station acquisition of the wireless communication system, the method is further used with the indication of the range in which one or more base stations support the power boost mode of operation. Transmitting the reference signal so that the terminal device can derive one or more characteristics of the received reference signal.

  According to a particular embodiment, the indication of the range in which one or more base stations in the wireless communication system supports the power boost mode of operation includes an indication that is unique to the base station.

  According to a particular embodiment, the indication of the range in which one or more base stations support the power boost mode of operation in the wireless communication system is applicable to a plurality of base stations.

  According to a particular embodiment, the indication is related to the range in which one or more of the base stations in the wireless communication system supports the power boost mode of operation, and other bases in the wireless communication system. It is not related to the range in which the station supports the power boost mode of operation.

  According to a particular embodiment, the indication is related to the range in which at least one other base station supports the power boost mode of operation within the wireless communication system.

  According to a particular embodiment, the terminal device is connected to the base station and not connected to the at least one other base station.

  According to a particular embodiment, the method further comprises receiving from the at least one further base station an indication of the range in which the at least one further base station supports the power boost mode of operation in the wireless communication system; including.

  According to a particular embodiment, the terminal device is connected to the base station when the indication of the range in which one or more base stations support the power boost mode of operation is conveyed to the terminal device. Not.

  According to certain embodiments, the indication of the range in which one or more base stations support the power boost mode of operation is implicit in connection with transmissions to carry other information. Is transferred to the terminal device.

  According to a particular embodiment, the step of carrying the indication of the range in which one or more base stations within the wireless communication system support the power boost mode of operation is selected according to the indication carried. Transmitting a broadcast signal using a transmission resource.

  According to a particular embodiment, the broadcast signal includes a synchronization signal.

  According to a particular embodiment, the indication of the range in which one or more base stations support the power boost mode of operation is conveyed to the terminal device using an explicit signal.

  According to a particular embodiment, the explicit signal comprises a system information signal.

  According to another aspect of the present disclosure, at least some downlink communication is performed using a limited subset of transmission resources selected from within a system frequency band, and the channel bandwidth is narrower than the system frequency band A method for operating a base station in a wireless communication system comprising one or more base stations that support a virtual carrier mode of operation, including a limited bandwidth downlink channel having: In order to define a range in which a base station supports the virtual carrier operation mode and to control acquisition of a base station of the wireless communication system performed by the terminal device, one or more base stations operate the virtual carrier operation One or more so that the terminal device can consider the indication of the range to support the mode The earth station carries an indication of the range to support the power boost operation mode to the terminal devices operating in the wireless communication system includes, a method is provided.

  According to a particular embodiment, the indication is related to the range in which at least one other base station supports the virtual carrier mode of operation within the wireless communication system.

  According to a particular embodiment, the terminal device is connected to the base station and not connected to the at least one other base station.

  According to a particular embodiment, the method further comprises receiving from the at least one further base station an indication of the range in which the at least one further base station supports the virtual carrier mode of operation in the wireless communication system. including.

  According to a particular embodiment, the indication of the range in which one or more base stations support the virtual carrier mode of operation is conveyed to the terminal device using an explicit signal.

  According to a particular embodiment, the explicit signal comprises a system information signal.

  In accordance with another aspect of the present invention, a power boost mode of operation in which the base station's available transmit power is concentrated to provide enhanced transmit power within a subset of the base station's available transmit resources. A base station is provided for use in a wireless communication system comprising one or more base stations to support, the base station defining a range in which the one or more base stations support the power boost mode of operation, and In order to control the acquisition of the base station of the wireless communication system performed by the terminal device, the terminal device can consider the indication of the range in which one or more base stations support the power boost operation mode. As such, one or more base stations operate in the wireless communication system to indicate an indication of the range that supports the power boost mode of operation. Configured to carry on.

  According to another aspect of the present disclosure, at least some downlink communication is performed using a limited subset of transmission resources selected from within a system frequency band, and the channel bandwidth is narrower than the system frequency band One or more base stations for use in a wireless communication system comprising one or more base stations supporting a virtual carrier mode of operation, including a limited bandwidth downlink channel having Defines a range supporting the virtual carrier operation mode, and one or a plurality of base stations support the virtual carrier operation mode in order to control acquisition of the base station of the wireless communication system performed by the terminal device One or more base stations allow the power supply to allow the terminal device to consider the indication of the range. Constructed an indication of the range to support strike operation mode to carry the terminal device operating within the wireless communication system, a base station is provided.

  As will be appreciated, the features and aspects of the invention described above in connection with the first and other aspects of the invention are equally applicable to embodiments of the invention, and are identified above as appropriate. In addition to the above-described combinations, the embodiments may be combined with embodiments according to other aspects of the present invention.

Embodiments of the present disclosure are described by way of example only with reference to the accompanying drawings, in which like parts are provided with corresponding reference numerals.
FIGS. 1A and 1B show example plots of transmit power versus frequency for two modes of operation for a base station in an LTE-based wireless communication network operating at the maximum allowable power output of the base station. FIG. 2 is a schematic diagram illustrating an example of a conventional mobile communication network. FIG. 3 provides a schematic diagram of a conventional LTE radio frame. FIG. 4 provides a schematic diagram illustrating an example of a conventional LTE downlink radio subframe. FIG. 5 provides a schematic diagram illustrating a conventional LTE “camp-on” procedure FIG. 6 schematically represents several elements of a wireless communication system according to some embodiments of the invention. FIG. 7 is a ladder diagram that schematically illustrates certain operational aspects of the components of the wireless communication system of FIG. 6, in accordance with some embodiments of the present invention. FIG. 8 is a flow diagram schematically illustrating some operational aspects of a terminal device according to some embodiments of the invention. FIG. 9 is a ladder diagram that schematically illustrates some operational aspects of the components of the wireless communication system of FIG. 6, in accordance with some embodiments of the present invention.

  FIG. 2 provides a schematic diagram for explaining some basic functions of a wireless communication network / system operating according to LTE principles. Each of the various elements and modes of operation in Figure 2 are well known in the relevant standards governed and defined by the 3GPP (RTM) organization, and for example in Holma, H. and Toskala A. [1] As such, this content is described in many books.

  The network includes a plurality of base stations 101 connected to the core network 102. Each base station provides a coverage area 103 (ie, a cell) where data can be communicated to and from the terminal device 104. Data is transmitted from the base station 101 to the terminal devices 104 in the respective coverage areas 103 via the radio downlink. Data is transmitted from the terminal device 104 to the base station 101 via a radio uplink. The core network 102 routes data to and from the terminal device 104 via each base station 101, and provides functions such as authentication, mobility management, and accounting. A terminal device may also be referred to as a mobile station, user equipment (UE), user terminal, mobile radio, and so on. A base station may also be referred to as a transceiver station / NodeB / e-NodeB or the like.

  Mobile communication systems, such as those deployed in accordance with the Long Term Evolution (LTE) architecture defined by 3GPP, use orthogonal frequency division multiplexing (OFDM) based interfaces for radio downlinks (so-called OFDMA) and radio uplinks (so-called so-called OFDMA). Single carrier frequency division multiplexing based interface for SC-FDMA). FIG. 3 shows a schematic diagram illustrating an OFDM-based LTE downlink radio frame 201. An LTE downlink radio frame is transmitted from an LTE base station (known as Extended Node B) and lasts 10 ms. The downlink radio frame includes 10 subframes, and each subframe lasts 1 ms. A primary synchronization signal (PSS) and a secondary synchronization signal (SSS) are transmitted in the first and sixth subframes of the LTE frame. The physical broadcast channel (PBCH) is transmitted in the first subframe of the LTE frame.

  FIG. 4 is a schematic diagram of a grid illustrating an exemplary structure of a conventional downlink LTE subframe. A subframe includes a predetermined number of symbols transmitted over a 1 ms period. Each symbol includes a predetermined number of orthogonal subcarriers distributed over the bandwidth of the downlink radio carrier.

  The exemplary subframe shown in FIG. 4 includes 14 symbols and 1200 subcarriers spaced across a 20 MHz bandwidth. In LTE, the minimum transmission allocation for user data is a resource block including 12 subcarriers transmitted in one slot (0.5 subframe). For clarity, in FIG. 4 each individual resource element (the resource element contains a single symbol on a single subcarrier) is not shown and instead each individual resource in the subframe grid Correspond to 12 subcarriers transmitted in one symbol.

  FIG. 4 shows resource allocation for four LTE terminals 340, 341, 342, and 343. For example, the resource allocation 342 for the first LTE terminal (UE1) spans 5 blocks of 12 subcarriers (ie 60 subcarriers), and the resource allocation 343 for the second LTE terminal (UE2) is 12 subcarriers The same applies to the six blocks.

  Control channel data can vary between 1 and 3 symbols for channel bandwidths where n is greater than 3 MHz and n is between 2 and 4 symbols for channel bandwidths of 1.4 MHz. Transmitted in the control region 300 of the subframe (indicated by the dotted slash in FIG. 4) containing the first n symbols of the subframe, which can vary between. In order to provide a specific example, the following description relates to a carrier with a channel bandwidth of 3 MHz or more and a maximum value of n of 3. Data transmitted in the control region 300 includes data transmitted on the physical downlink control channel (PDCCH), the physical control format indicator channel (PCFICH), and the physical HARQ indicator channel (PHICH).

  The PDCCH includes control data indicating which subcarrier on which symbol of a subframe is allocated to a specific LTE device. Therefore, in the PDCCH data transmitted in the control region 300 of the subframe shown in FIG. 4, the resource block identified by reference numeral 342 is assigned to UE1, and the resource identified by reference numeral 343 is identified as UE2. It may indicate that a block is allocated.

  The PCFICH includes control data indicating the size of the control area (that is, between one and three symbols).

  The PHICH includes HARQ (Hybrid Automatic Request) data indicating whether the uplink data transmitted previously has been successfully received by the network.

  The symbols in the central band 310 of the time-frequency resource grid are used for transmission of information including primary synchronization signal (PSS), secondary synchronization signal (SSS), and physical broadcast channel (PBCH). This central band 310 is typically 72 subcarrier widths (corresponding to a transmission bandwidth of 1.08 MHz). PSS and SSS are synchronization signals that, when detected, allow the LTE terminal to achieve frame synchronization and determine the cell identification information of the extended NodeB that is transmitting the downlink signal. The PBCH carries information about the cell, including a master information block (MIB) that contains parameters used by the LTE terminal to successfully connect to the cell. Data transmitted to individual LTE terminals on the physical downlink shared channel (PDSCH) may be transmitted in other resource elements of the subframe.

Figure 4 also shows the region of the PDSCH over a bandwidth of _{R 344} includes system information. A conventional LTE frame also includes a reference signal not shown in FIG. 4 for clarity.

  The number of subcarriers in the LTE channel can vary depending on the configuration of the transmission network. Typically, this change is from 72 subcarriers contained within the 1.4 MHz channel bandwidth to 1200 subcarriers contained within the 20 MHz channel bandwidth (see FIG. 4). As shown). As is known in the art, subcarriers carrying data transmitted on PDCCH, PCFICH and PHICH are generally distributed across the bandwidth of the subframe to provide frequency diversity. The Thus, a conventional LTE device must be able to receive the entire subframe bandwidth in order to receive and decode the control region.

  FIG. 5 shows an LTE “camp-on” process, ie, a process initiated by a terminal so that a downlink transmission transmitted by a base station via a downlink channel can be decoded. Using this process, the terminal can identify the part of the transmission that includes the system information of the cell and such decoding configuration information for the cell.

  As can be seen in FIG. 5, in the conventional LTE camp-on procedure, the terminal first synchronizes with the base station using PSS and SSS in the central band (step 400) and then decodes the PBCH (step 401). ). When the terminal performs steps 400 and 401, the terminal synchronizes with the base station.

For each subframe, the terminal then decodes the PCFICH distributed over the entire bandwidth of carrier 320 (step 402). As mentioned above, LTE downlink carriers can be 20 MHz wide (1200 subcarriers), so LTE terminals have the ability to receive and decode 20 MHz bandwidth transmissions to decode PCFICH There is a need. In the PCFICH decoding phase with a 20 MHz carrier band, the terminal operates with a much larger bandwidth (R ₃₂₀ bandwidth) than between steps 400 and 401 (R ₃₁₀ bandwidth) related to synchronization and PBCH decoding. To do.

  Specifically, to identify the transmission of system information and to identify the resource allocation of the terminal, the terminal then checks the location of the PHICH (step 403) and decodes the PDCCH (step 404). Resource allocation is used by the terminal not only to retrieve system information and data in the PDSCH, but also to inform the terminal of any transmission resources allowed on the PUSCH. Both system information and UE specific resource allocation are transmitted in PDSCH and scheduled in carrier band 320. Steps 403 and 404 also require the terminal to operate at R320 for the full bandwidth of the carrier band.

In steps 402 to 404, the terminal decodes information included in control region 300 of the subframe. As described above, in LTE, the control region extends over region R ₃₂₀ , and as described above, over the control region 300 of the carrier that occupies the first one, two, or three OFDM symbols of each subframe as described above. Two control channels (PCFICH, PHICH and PDCCH) are discovered. In a subframe, the control channel generally does not use all resource elements in the control region 300, but an LTE terminal may receive the entire control region 300 to decode each of the three control channels simultaneously. As it must be possible, the control channels are distributed over the entire area.

  The terminal can then decode the PDSCH containing system information or data transmitted for this terminal (step 405).

As described above, in general, in an LTE subframe, PDSCH occupies a group of resource elements that are neither a control region nor a resource element occupied by PSS, SSS, or PBCH. The data in the blocks of resource elements 340, 341, 342, 343 allocated to different mobile communication terminals (UEs) shown in FIG. 4 has a bandwidth that is smaller than the bandwidth of the entire carrier, but the resource of PDSCH is UE In order to identify whether the PDCCH indicates that it should be decoded and to be decoded, and to decode these blocks, the terminal first receives the PDCCH extending over the frequency range R ₃₂₀ . After receiving the entire subframe, the UE can then decode the PDSCH (if any) in the relevant frequency domain indicated by the PDCCH. Therefore, for example, the above-described UE1 decodes the data in the resource block 342 after decoding the entire control region 300.

  As described above, with respect to wireless communication with a base station, it is expected that a particular terminal device may be in a location with a relatively high transmission loss. For example, an MTC type terminal device associated with a smart meter application may be installed underground. This can indicate that a specific device needs a base station that transmits at a very high power level compared to other terminal devices connected to the base station in order to support reliable communication. It is anticipated that MTC type terminal equipment may often be in a “hard to reach” place than other types of terminal equipment, but as understood, As described in the specification, the problems related to coverage expansion can be applied to non-MTC type terminal devices as well. Schematically shown in FIG. 1B and as described above, supports reliable communication with terminal equipment in a relatively poor coverage area rather than simply increasing the overall transmit power from the base station One proposal for this is to concentrate the amount of base station transmit power on a relatively high power transmission of a subset of frequencies over a bandwidth that is smaller than the base station's normal operating bandwidth. However, as described above, a terminal device attempting to camp on / connect to a specific base station according to the prior art generally decodes relatively high level system information associated with the base station by the terminal device. Until you can, you won't notice a situation where the base station can support power boost. In other words, it is necessary to go through the process of FIG. 5 before the terminal device determines whether the base station can actually support communication with the terminal device in the reliable power boost operation mode. It is. Certain embodiments of the present invention provide terminal devices with information regarding the capabilities of base stations operating in power boost mode from the perspective of reducing wasted camp-on attempts (eg, base stations support power boost). (And whether and when it is supported).

  FIG. 6 is a schematic diagram illustrating a portion of a communication system 1400 configured in accordance with an embodiment of the present invention. In this example, communication system 1400 is broadly based on an LTE type architecture. Many aspects of the operation of communication system 1400 are known and understood and will not be described in detail here for the sake of brevity. Operational aspects of communication system 1400 not specifically described herein may be implemented according to any known technique, eg, according to current LTE standards.

  Shown in FIG. 6 are three communication cells 1404A, B, C supported by respective base stations 1401A, B, C connected to the core network 1408. Although the communication cells are virtually shown in FIG. 6 as adjacent hexagons, in practice, the individual terminals are located within the virtual geographical coverage area of multiple base stations. It will be appreciated that the respective coverage areas associated with different base stations overlap so that For example, it is assumed here that the terminal device 1403 according to the embodiment of the present invention is located in a virtual coverage area of all three base stations 1401A, B, and C. This is schematically illustrated in FIG. 6 by the presence of the terminal device 1403 at the location represented by the point where the three communication cells 1404A, B, C represented by the three hexagons schematically represent. Therefore, in principle, the terminal device 1403 is connected to any of the base stations 1401A, B, and C (that is, connected or camped on). In accordance with common practice, the terms base station and cell may sometimes be used interchangeably herein, for example, a process of a terminal device that connects to a radio access portion of a wireless communication system connects to a cell or Reference may be made to connecting to a base station.

  In general, it will be appreciated that a system such as that shown in FIG. 6 includes a number of cells configured to provide coverage over a more expanded geographic area. Like a conventional LTE type network, each base station 1401A, B, C can communicate with each other via a so-called X2 interface that interconnects the base stations in a peer-to-peer fashion.

  For the sake of illustration, the two base stations 1401A, 1402B envisioned here are configured to support the power boost mode of operation, while the base station 1401C is configured to support the power boost mode of operation. Absent.

  Referring to FIG. 6, communication cell 1404A includes base station (enhanced NodeB / base station) 1401A connected to core network 1408 in this way. Base station 1401A includes a transceiver unit 1410A for transmitting and receiving radio signals and a control unit 1411A configured to control base station 1401A. The control unit 1411A may include various subunits such as a scheduling unit 1409A and other functional units for providing functionality according to embodiments of the present invention, as further described below. These subunits can be implemented as functions of individual hardware elements or appropriately configured control units. Accordingly, the control unit 1411A is a processor suitably programmed / configured to provide the desired functionality described herein using conventional programming / configuration techniques for equipment in a wireless communication system. Units may be included. The transceiver unit 1410A and the control unit 1411A are shown schematically in FIG. 6 as separate elements for ease of presentation. However, as will be appreciated, the functions of these units can be provided in a variety of different ways in the following conventions established in the art, eg a single appropriately programmed connected to an antenna. Use integrated circuits. It will be appreciated that the base station 1401A generally includes various other elements related to its operating function.

  Base station 1401A can communicate with multiple conventional LTE terminals 1402A within the coverage area of cell 1404A in accordance with conventional techniques. Base station 1401A is configured to transmit downlink data using a subframe structure that is generally in accordance with that shown in FIG. This is performed in the power boost mode of operation shown schematically in FIGS. 1A and 1B.

  As mentioned above, for the sake of illustration, base stations 1401A, 1401B associated with communication cells 1404A, 1404B both support power boost mode of operation, while base station 1401C associated with communication cell 1404C is in power boost mode of operation. It is assumed here that it does not support. Various elements and functions related to the communication cell 1404B are essentially the same as those of the communication cell 1404A. Similarly, the various elements and functions associated with communication cell 1404C are essentially the same as communication cell 1404A (base station 1401C of communication cell 1404C does not support the power boost mode of operation assumed in this example) Except that). With this in mind, it is understood that the various elements of communication cells 1404B, 1404C shown in FIG. 6 are the same as the corresponding elements of communication cell 1404A and are understood from the corresponding elements of communication cell 1404A. (Except that base station 1401C cannot support power boost transmission).

  As described above, the terminal device 1403 according to the embodiment of the present invention also includes virtual terminals for the three communication cells 1404A, B, and C associated with the three base stations 1401A, B, and C illustrated in FIG. In a location within a large geographic coverage area. The terminal device 1403 may be based on any conventional terminal device adapted to support operation according to the embodiments of the invention described herein.

  The terminal device 1403 includes a transmission / reception unit 1405 for transmitting and receiving radio signals, and a control unit 1407 configured to control the device 1403. The control unit 1407 may include various subunits for providing functionality according to embodiments of the invention, as described herein. These subunits can be implemented as suitably configured functions of individual hardware elements or control units. Thus, the control unit 1407 is a processor unit suitably programmed / configured to provide the desired functionality described herein using conventional programming / configuration techniques for equipment in a wireless communication system. May be included. The transceiver unit 1405 and the control unit 1407 are shown schematically as separate elements in FIG. 6 to facilitate the representation in the figure. However, it will be understood that the functions of these units can be provided in a variety of different ways in the following conventions established in the art, for example to use a single appropriately programmed integrated circuit. Will be done. In general, it will be appreciated that the terminal device 1403 includes various other elements related to the functionality of its operation. The operation mode of the terminal device 1403 not described in the present specification can be implemented according to the prior art.

  An operation mode in which the terminal device 1403 controls acquisition of one of the base stations 1401A, B, and C of the wireless communication system 1400 according to the embodiment of the present invention is shown below. In this example, it is assumed that base station 1401C does not support the power boost mode of operation, and the operation of this base station may be completely conventional.

  Based on information received from one or more base stations regarding the range in which one or more base stations of the wireless communication system support the power boost mode of operation, the base station of the wireless communication system of the terminal device is acquired. Various embodiments controlled by the terminal device are shown. In this respect, controlling the acquisition can be considered to correspond to the camp-on / cell attach control through a procedure in which the terminal apparatus receives a signal from a specific base station. The terms capture and connection (and derivatives thereof) can be used interchangeably throughout this specification, and should be construed accordingly unless the context requires otherwise. In some examples, the acquisition may correspond to a cell selection procedure, for example when the terminal device is first powered on. In another example, when the terminal device is camping on another base station, for example, the step of controlling acquisition may correspond to control of cell reselection or handover procedure.

  Considering the functions of different base stations with respect to the power boost mode of operation, the terminal device may be able to control the acquisition of the base station according to the embodiment of the present invention more efficiently. For example, if the terminal device relies on power boost to reliably receive data, avoid attempting to connect to a base station that does not support the power boost mode of operation and / or for that base station May delay connecting to the base station until power boost is available.

  In the first example, it is assumed that the terminal device 1403 is just powered on and needs to determine which available base stations 1401A, 1401B, 1401C it will connect / camp on. According to standard techniques, in these situations, terminal devices that are usually in the coverage area of multiple cells are received from different cells to perform radio link state measurements for communications from each base station. And measuring a signal to connect to one of the base stations based on the measured radio link condition. However, the drawback of this approach is that the terminal device does not know how much the radio link state is improved by the availability of power boost. Thus, according to a particular embodiment of the invention, in order to assist the process of connecting to the network via a suitable base station, the terminal device provides an indication of the range within which the base station in the wireless communication network supports power boost. You may receive it.

  In some embodiments, each of the individual base stations that support the power boost mode of operation is configured to implicitly communicate to the terminal device their specific indication of the range in which they support the power boost mode. Yes. In some examples, the indication may be conveyed in connection with a broadcast signal received at an idle mode terminal. For example, in some cases, the indication of the range in which the base station supports the power boost mode (ie, the indication of power boost availability (PBA)) is implicitly synchronized depending on the transmission resource selected by the base station It may be carried in connection with a broadcast signal such as a signal. The power boost availability (PBA) indication may indicate, for example, the level of power boost for a particular base station, the time of availability, or simply the presence. As already mentioned, for example, how does the terminal equipment handle signal measurements for handover as well as cell selection / reselection to take into account the potentially improved suitability of cells that support power boosting? Before launching to connect to the cell that the PBA instructions indicate that there is a better coverage may be available at some particular point in the day, as well as managing what to run and respond to By managing how the terminal device goes into sleep mode, this information can assist in controlling the terminal device's acquisition of the base station of that terminal device.

  More generally, considering the different base station functions regarding the power boost operation mode, for example, if the terminal device needs the power boost operation mode to reliably receive data, the power boost operation mode is supported. By avoiding attempts to attach to non-existing base stations, or by delaying the procedure to connect to the base station until a power boost is shown as available to the base station It is possible to control the acquisition of the base station. In this respect, connection control can be considered to correspond to camp-on / cell attach control via a procedure for a terminal device to connect to a specific base station. In some examples, for example, when the terminal device is first powered up, the connection corresponds to a cell selection procedure. In another example, for example, in an example in which the terminal device moves to another base station, the connection may correspond to a cell reselection procedure.

  In one embodiment, the base station may provide a repetition of a synchronization signal sequence such as a primary synchronization sequence (PSS) and a secondary synchronization sequence (SSS) used in an LTE type network. As mentioned above, in order to assist the powered-on terminal device, the synchronization signal is provided with a specific designated transmission resource according to a standard implemented so that the synchronization signal can be easily retrieved, thereby allowing the network to In order to assist in the acquisition of further signals related to the connection, the terminal device can synchronize with the transmission from the base station more quickly.

  The co-pending UK patent application number GB1305233.7 (2) filed on March 21, 2013 and GB1350234.5 (3) filed on March 21, 2013 are the physical cells searched by the terminal device Disclosed is a mechanism for communicating information about identifier (PCI) ranges and / or SSS values. This is accomplished by changing the subframe or OFDM symbol where some additional repetition (s) of PSS / SSS occurs. A similar approach may be employed in embodiments of the invention where the base station wishes to broadcast a specific PBA indication by selecting an appropriate form of synchronization signal repetition depending on the information carried. For example, in a simple case, the network may simply allow the base station to indicate whether the base station can currently adapt to the power boost mode. In practice, the base station may introduce this synchronization signal repetition into its downlink subframe at a pre-specified location, for example by offsetting it from the conventional synchronization signal at a specific time and / or frequency. The function can be notified at a point. Therefore, a terminal device that detects such repetition assumes that the base station is notifying its function of operating in power boost mode and considers this information when determining how the terminal device connects to the network. May be. This is generally transmitted with a much higher degree of redundancy than PDSCH transmission, so that the terminal device can reliably receive other signals such as synchronization signals, for example in the downlink in a wireless communication system. Note that a power boost is required to reliably receive the shared channel (PDSCH). Therefore, it is expected that a terminal device in a position where it is difficult to reliably receive a PDSCH transmission nevertheless reliably receives another signal.

  Different mappings between broadcast signals and transmission resources used for information regarding the power boost function may be defined according to the standard. For example, different positions (in the time / frequency domain) for the repetition of the synchronization signal may be associated with different information conveyed regarding the range in which one or more base stations support the power boost mode of operation. In this way, a base station may define a range in which it (or other base station, as will be further described below) can support the power boost mode, which fixes the base station characteristics or Depending on how much confusion the power boost mode of operation causes for other users of the network, for example, according to a predefined mapping between transmission characteristics and information This information is communicated implicitly by appropriately selecting the transmission characteristics of the broadcast signal, such as a synchronized signal. As will be appreciated, multiple “bits” (different states) of information are conveyed by increasing the number of options that the base station can select for its broadcast signal. For example, potential multiple repetitions of the synchronization signal can provide a state that is differentiated to indicate a different range of availability of more corresponding power boosts. A terminal device that expects to need to operate reliably with extended coverage for PDSCH / PDCCH may simply choose not to connect to the cell associated with an indication of a lack of power boost availability. . This saves the terminal equipment power with respect to the PRACH and there is uplink interference (and therefore re-transmission) since there is a corresponding reduction in the terminal equipment trying to acquire cells that cannot support the power boost need of the terminal equipment. Transmission can also be reduced.

As described above, the PBA indication may be selected by the base station to convey various types of information regarding the extent to which one or more base stations support power boost in the network. For example, depending on the implementation, a PBA indication carried from the base station to the terminal device can be used to indicate any of the following, according to some embodiments.
(I) Availability of any power boost for one or more base stations (ii) For any power density boost level available, eg, initial / nominal power level available without power boost Power enhancement available (eg, in dB) for the resource where the power boosted transmission takes place.
(Iii) The time (or amount of power boost) at which power boost is expected to be available. For example, this can be based on a fairly coarse division of days to fit the available number of states of the PBA indication mechanism for a given implementation. In one simple example, the range in which the base station supports power boost corresponds to support power boost at a high boost level (power enhancement) between 0:00 and 5:30, and between 22 and 0 The power boost may be supported at a low boost level, and the power boost may not be supported between 5:30 and 22:00. This range of power boost support is conveyed to the terminal device with a three-state PBA indication. Specific implications for situations such as “high” and “low” (eg, in terms of actual power level enhancements) can be defined in various ways, for example, network operators outside the standard And terminal equipment manufacturers may agree or may be described in standard specifications.
(Iv) Power boost is available on the downlink physical channel. (For example, if power boost is supported on some downlink physical channels but not others).

  The method of operation of the components of the wireless communication system 1400 according to some embodiments of the invention illustrated in FIG. 6 is described below. In the first example described, it is assumed that the terminal device 1403 is not initially connected (attached / camped on) to any base station.

  As in the conventional LTE type network, in RRC idle mode, the terminal device detects the presence of available base stations / cells and measures their RSRP / RSRQ levels. Based on these measurement results, a base station to be attached by the terminal device is selected from the ranking based on the measurement values. For example, when the terminal device transitions to the RRC connection mode, the terminal device is selected for various terminal device procedures such as receiving a paging message, reading system information (SI), and thus a random access procedure. Use base station / cell.

  After the terminal device is turned on, the initial cell selection is generally performed immediately. In accordance with standard techniques, the newly powered terminal device starts a scan of the supported bands, the terminal according to the preferred operator's network (ie PLMN identifier in the SIM card) and the established cell selection procedure Based on the measurement result of the device, the cell to camp on is selected. Further details of these procedures are understood in the context of LTE type networks, for example the 3GPP document ETSI TS136304 V11.2.0 (2013-02) / 3GPP TS36.304 version 11.2.0 Release 11 (4).

  Subsequent cell selection procedures after the initial cell selection procedure are often referred to as “cell reselection” procedures in LTE. When cell reselection is performed, the terminal device searches for a neighboring cell having a better RSRP / RSRQ than the currently selected cell. Although the reselection criteria / procedure is considered a separate procedure from the (initial) cell selection, the principles described herein apply equally to both types of procedures in many respects. In ETSI TS136304 V11.2.0 (2013-02) / 3GPP TS 36.304 version 11.2.0 Release 11 (4), further details of the cell reselection procedure are also understood in the context of LTE type networks.

  As described above, the amount of information conveyed to the terminal device regarding the functions related to the power boost operation mode of the base station may differ depending on different implementations. In some examples, a simple 1-bit indication of whether power boost is available in the cell (eg, at a fixed predetermined level) may be used, which is a “single level” indication May be called. For example, a single level indication may be provided for a given base station depending on whether the base station is broadcasting a repetition of a synchronization signal on a particular transmission resource defined for this purpose. . Some other examples can carry more than one bit of information. For example, the indication of the range in which the base station supports power boost may include an indication of the number of different possible power boost levels provided by the cell, which is referred to as a “multi-level” indication May be. The latter may occur if a cell can change its power boost over time, or if the network as a whole supports multiple power boost levels, so an indication of the PBA level per cell is desired.

Based on the above two characteristics, four different cases are considered for an idle mode terminal:
・ Cell selection using single-level PBA instruction ・ Cell selection using multi-level PBA instruction ・ Cell re-selection using single-level PBA instruction ・ Cell re-selection using multi-level PBA instruction

  Examples of these different cases will be described below. However, as will be appreciated, the basic principles of operation are the same for each case to a large extent. In each case, it is assumed that the terminal device 1403 uses information regarding the range in which various base stations support power boost, received from one or more base stations shown in FIG.

  FIG. 7 is a ladder diagram schematically illustrating a part of operation surfaces of the terminal device 1403 and the base stations 1401A, B, and C of FIG. 6, and the initial cell selection by a single PBA instruction according to the embodiment of the present invention. It is an example. Accordingly, the PBA indication is provided merely to identify whether the base station supports power boost. For example, the level of power boost in terms of potential power increase in dB of transmission resources where power is concentrated during power boost may be predefined according to criteria. For example, an operational criterion associated with a wireless communication system may define a power boost mode that consists of a four-fold increase (about 6 dB) of available power within a quarter of available transmission resources. .

  Therefore, in the first step, for example, the terminal device is activated after the first power-on / rest period. According to the conventional LTE principle, the terminal device scans for a synchronization signal broadcast by surrounding base stations. As described above, with respect to the example of FIG. 6, it is assumed that the terminal device is in the virtual coverage area of all three base stations 1401A, B, and C. Accordingly, as schematically shown in FIG. 7, the terminal device can receive primary (PSS) and secondary (SSS) signals from each of the base stations. In accordance with the principles described above, each base station that supports power boost can be powered by transmitting (eg, repetitive signals) associated with their synchronization signals, particularly over transmission resources defined for this purpose. Configured to show boost. This is shown schematically in FIG. 7 for base stations that support power boost (ie, base stations 1401A and 1401B) by labeling them as [PB] in relation to their PSS / SSS signal representation. . A base station that does not support power boost (such as base station 1401C) does not perform a transmission related to the synchronization signal on a predefined transmission resource, thereby using its power boost Demonstrate the functions that cannot be performed.

  The terminal device 1403 is configured to search for repetition of the synchronization signal on the transmission resource defined to identify the availability of power boost, and if such a synchronization signal is detected, the terminal device 1403 determines that the corresponding base station supports power boost. Accordingly, the terminal device 1403 determines that the base stations 1401A and 1401B support power boost, while the base station 1401C does not support it. Accordingly, the terminal device 1403 reaches a stage where the terminal device identifies which base stations are in range and which of them support power boost.

  In the next two stages shown in FIG. 7, the terminal device 1403 verifies which base station corresponds to the preferred (priority) PLMN, and performs RSRP measurement for each base station. Here, it is assumed that all three base stations correspond to the priority PLMN of the terminal device, and thus RSRP measurement is performed for each base station / cell. These two stages can be performed according to conventional techniques.

  Taking the RSRP measurements and considering the information received before this stage regarding the range over which various base stations support power boost, the next stage of operation for the terminal device 1403 shown in FIG. 7 is the cell ranking stage. And a cell selection stage. At this stage, taking into account the capability to support RSRP measurements and power boost for each base station, the terminal equipment determines how it is then most appropriate to connect by To control whether to connect to the base station of the wireless communication system.

  In general, the cell ranking phase may follow the same general principles as the traditional cell attach procedure, except that the base station considers the extent to which the base station supports power boost in addition to taking RSRP measurements into account. . One way to do this is to substantially improve RSRP measurements for base stations that support power boost. For example, the reference signal received power measurement (RSRP) for base stations that support power boost has been modified for cell ranking corresponding to measured RSRP plus and offset corresponding to the available power boost extensions It may be replaced with RSRP. For example, if the specification defines power boost as corresponding to a 6 dB enhancement, RSRP measurements for base stations that indicate that they support power boost may be increased by 6 dB. The RSRP thus modified reflects the channel characteristics that can be achieved when power boost is active for a given base station.

  For example, if the RSRP measurement for base station 1401C (which does not support power boost) is 2dB higher than for base station 1401A (which supports power boost) and 3dB higher than for 1401B (which also supports power boost) If the terminal device 1403 determines, the terminal device that will follow the conventional cell selection technique determines that the base station 1401C should be selected to connect to the network. However, according to embodiments of the present invention, in fact, it provides an indication of the possibility of 6 dB power enhancement via power boost, so at this early stage in the attach procedure, base station 1401A receives received signal power. Can recognize that the terminal device has a high possibility. Therefore, according to the embodiment of the present invention, the terminal device may instead determine that the base station 1401A is the first base station for actually connecting to the network. This is schematically illustrated in FIG. 7 by the display in which cell A is selected in the cell selection stage.

  When a base station (cell) for connection to the network is selected according to the embodiment of the present invention, the terminal device 1403 may proceed with the procedure according to the conventional technology. Thus, as schematically represented in FIG. 7, the base station may proceed to receive and decode the physical broadcast channel (PBCH) transmitted by the selected base station, in which case Base station 1401A provides the cell 1404A and follows the rest of the camp-on procedure schematically represented in FIG. 5 to derive system information and the like.

  Therefore, according to the technique described above with reference to FIG. 7, it may happen to be associated with the highest RSRP, but because it does not support power boost, it cannot ultimately support reliable communication with the terminal equipment. The terminal device can avoid performing an unnecessary camp-on procedure for the base station 1401C.

  FIG. 8 is a flow diagram illustrating some aspects of the operation of the terminal device 1403 in accordance with the implementation of an embodiment of the present invention, as generally described above with reference to FIG. Although steps S2 to S6 are shown as representing steps associated with one base station, it will be understood that the corresponding steps are performed for other base stations within range of the terminal equipment. The steps corresponding to steps S2 to S6 may thus be performed for multiple base stations in either a continuous, parallel or interleaved manner.

  For example, when the terminal device is first turned on, the process starts in step S1.

  In step S2, the terminal apparatus detects a synchronization signal from a base station within range.

  In step S3, the terminal apparatus determines whether the signal received from the base station includes an indication of availability of power boost.

  In step S4, the terminal apparatus determines a power boost level corresponding to the range indicated as being available for the base station. For example, if a power boost indication is not associated with the synchronization signal for this particular base station, the terminal will indicate that the power boost available at that base station (eg, for base station 1401C in FIG. 6) is 0 dB The device can be identified. On the other hand, when the terminal apparatus determines that there is an instruction that the base station supports power boost, the instruction may be changed to a corresponding power boost level. For example, in the case of the above example, a fixed potential power boost level of 6dB. For example, the power boost level may be referred to as an offset.

  In step S5, the terminal apparatus performs RSRP measurement on the base station.

  In step S6, the terminal device adjusts the measured RSRP for the base station to take into account the potential power boost enhancement (offset) defined in step S4. For example, a modified RSRP corresponding to the measured RSRP plus an available power boost level may be determined.

  In step S7, taking into account any potential improvement from the power boost, the terminal device determines whether the base station meets certain minimum requirements for selection from measurement of the reference signal. If a base station does not meet these requirements, it may be ignored from further consideration. On the other hand, if the base station meets these requirements, it can remain as a candidate for selection. The lowest selection criteria may broadly correspond to those applied in conventional LTE networks, but consider that power boosts, if any, are indicated to be available to the base station under consideration May be changed.

Thus, the base station may consider satisfying the lowest selection criteria if both of the following inequalities are satisfied:
RSRP + Offset> (Q _rxlevmin + Q _{rxlevminoffset} ) + Pcompensation (Equation 1)
RSRQ + Offset> (Q _qualmin + Q _{qualminoffset} ) (Formula 2)

These inequalities are closely related in traditional LTE type networks as described, for example, in the 3GPP document ETSI TS 136 304 V11.2.0 (2013-02) / 3GPP TS 36.304 V11.2.0 Release 11 (4). It will be appreciated that this corresponds to the analysis applied for cell selection. In each case, there are differences only on the left side of the inequality. In the case of the conventional LTE scheme, the left side of these inequalities respectively corresponds to just RSRP (in formula 1) and RSRQ (in formula 2), whereas according to the embodiment of the present invention, the left side of the inequality is available Modified to account for potential improvements (offsets) related to the level of power boost. For example, in both cases, the offset may be 6 dB according to an embodiment of the present invention. The various parameters listed on the right side of the above inequality are relevant, for example 3GPP TS 36.304 version 11.2.0 release 11 (4), for example they are defined according to the following table (see section 5.2.3.2) It is defined in the standard.

  Equations 1 and 2 show that the left side of the inequality is increased by the associated offset, but the same evaluation result is of course obtained by having the right side reduced by the respective offset.

  In step S8, taking into account the modified value of RSRP (ie, adding an offset of the available power boost level to the measured RSRP), the various values that satisfy the quality evaluation in step S7 according to the modified value of RSRP. The terminal device actually ranks the base station. Therefore, the terminal apparatus may select the base station with the highest corrected RSRP value as the base station with which the terminal apparatus continues the attach procedure.

  In step S9, the terminal device proceeds with the attachment to the selected cell / base station. Once the desired cell is selected, the attach (camping) procedure may continue as usual.

  It will be appreciated that other embodiments of the process depicted in FIGS. 7 and 8 may be modified. For example, in some implementations, it may be determined that the terminal device should not attempt to camp on a base station that does not support power boost. In this case, if the terminal apparatus determines in the step corresponding to step S3 in FIG. 8 that power boost is not available for a particular base station, the base station may be ignored from further consideration.

  Therefore, according to the embodiment of the present invention as described above, an indication of the range of power boost supported by the base station that the terminal device considers attaching is provided to the terminal device at an early stage, thereby connecting to the network. The terminal device can take this information into account when determining the most appropriate base station to do.

  In the example shown in FIG. 7 and FIG. 8, it is based on a single bit indication regarding the range in which base stations actually support power boost (ie, whether they support power boost), but in other examples, More information can be conveyed. As mentioned above, this is called a multilevel approach. For example, according to certain embodiments, different base stations may support different levels of power boost. For example, one base station can power boost by up to 3dB, while the other base station can power boost up to 9dB. Different predetermined arrangements of transmission resources for broadcast signal repetition may be associated with different power boost levels. Thus, the base station can specify the range in which it supports power boost (eg, at 3dB or 9dB, or any other value available for a particular implementation) and transmit for the synchronization signal Deliver this to the terminal device via an appropriate selection of resources. For example, one approach can indicate four states of power boost availability that correspond to power boost levels of 0 dB, 3 dB, 6 dB, and 9 dB (eg, based on selection of whether or not two signals repeat) You may do it. Individual base stations may define the power boost levels they support based on fixed configuration information or dynamically based on current traffic. For example, it may determine that a relatively congested base station should not supply any power boost because this reduces the ability to service other terminal devices. However, a relatively lightly loaded base station may operate using the maximum power boost mode for a particular terminal device with little impact on the overall operation for other terminal devices. You may decide what you can do.

  A multi-level approach is generally illustrated in FIG. 7 and FIG. 7 except that the terminal can determine different power boost enhancements / offsets for different base stations according to instructions provided corresponding to the base station synchronization signal. The approach of FIG. 8 may be followed. A corresponding cell ranking procedure can then be used for different base stations in determining whether the most appropriate base station to connect and a particular base station can meet the minimum requirements for selection. Different power boost levels may be considered.

  The examples described above with reference to FIGS. 7 and 8 have mainly focused on the initial cell acquisition process (cell selection). However, as noted above, similar principles can be widely applied during the cell reselection process. For example, when an idle mode terminal is already camping on the first cell / base station, for example, the quality of the signal associated with the first cell is degraded. It may appropriately consider moving to another cell. By actually using the same selection process as described above for the initial cell selection, the terminal device can perform the cell reselection procedure in consideration of the range in which different base stations provide power boost. However, it should be noted for cell reselection that the terminal device is already camping on the base station of the network and therefore has to connect to system information. Thus, according to some embodiments of the present invention, in a network that assists terminal devices in controlling the acquisition of their base stations, the information carried in the system information is supported by different base stations for power boosting. It may be used to provide a range indication. This type of approach may be provided in combination with the implicit signal approach described above, and may be provided specific to that approach, independent of the implicit approach.

Thus, according to some embodiments, the concept of a base station list that supports power boost in a wireless communication system and the potential features of power boost provided by the base station, eg, power boost level, power boost are available In view of time, etc., may be introduced. This may preferably be referred to as a whitelist of power boost availability. For example, the list may be broadcast by the base station in association with system information normally received by the terminal device connected to the base station. Therefore, the terminal apparatus already connected to the base station is easily provided with information regarding the range in which other base stations support power boost in the network. This information allows the terminal equipment to consider other base stations as the terminal equipment can take into account the improvements in radio link conditions expected to be achieved with respect to the channel conditions measured for various base stations depending on the availability of power boost. Can assist in determining whether to move to a station. The following table shows a power boost availability whitelist that associates communication cell identifiers (PCIs) with examples of power boost levels supported by each cell.

  Each base station may be configured to maintain a white list for communication with terminal devices connected to them. Based on communication with the base station regarding their targeted power boost support, for example, using the X2 interface between base stations with additional newly defined information elements, the list is (half ) It may be held dynamically. For example, individual base stations may communicate with neighboring base stations using X2 signals as they change support for power boost mode. Alternatively, the list may be (semi) static based on the network settings selected by the operator. Therefore, when the terminal device in the idle mode measures the RSRP / RSRQ of the cell ID 432, the measurement considering the potential 6 dB power boost improvement provided by the cell ID 432 can be modified.

  Therefore, according to some embodiments, the serving cell to which the terminal device is already connected may provide an indication of the PBA related to the neighboring cell. If the terminal is connected to a serving cell (but not necessarily, perhaps after deciding to connect in a way that takes into account the power boost availability indication as described above), the RRC configuration signal Used to carry PBA indications associated with base stations / cells. The terminal device can then use this information to determine whether or not to acquire a neighboring cell and potentially when to acquire a neighboring cell. For example, if it is reported that a neighboring cell can provide better service considering the availability of power density boost, the terminal device should abandon the serving cell and attach to the neighboring cell. It may be determined that it will be. This is done for the current serving cell, either through an explicit request that can then initiate a handover (HO) procedure, or if the uplink coverage in the serving cell is too bad, it simply introduces a new cell acquisition procedure for neighboring cells. Achieved by starting.

  In a variation of this approach, where the PBA indication includes information about the time of day that one or more base stations / cells can provide power density boost, the terminal device will probably power off until the time when power density boost is available The connection to the network may be controlled by deciding to shift to the power saving state corresponding to. And if a terminal device starts at the relevant time, it can connect to a power boost cell. This can represent a significant power saving advantage over the terminal device.

  As described above, neighbor cell PBA information is provided to idle terminal devices by including relevant information in system information (SI) broadcasts. The terminal device in the idle mode periodically checks the change of SI by checking the subframe configuration pattern for the paging PDCCH that identifies the PDSCH resource of the subframe in which the SI is held. This provides a mechanism for an idle mode terminal to receive an explicit signal regarding the function of one or more base stations regarding power boost operation.

  Note that in principle, a particular cell identifier can be associated with a negative power boost level. This has the effect of stopping the terminal from camping on this cell, even if the cell provides good RSRP / RSRQ measurements without any power boost, thereby Provides a mechanism to control the level.

  A simple version of the PBA whitelist may simply indicate a cell ID that can provide PBA at a given level (eg, specified or agreed upon). This approach is broadly equivalent to the “single level” indication approach described above.

  It will be appreciated that conventional LTE networks can define so-called white lists and black lists of PCI. The white list is a list of PCIs required for the terminal device to perform the reference signal measurement, and other cells may also be measured. The blacklist instructs the terminal device not to measure the blacklisted PCI for neighbor cell reselection. These PCI white and blacklist configurations are transmitted via RRC (Radio Resource Control) signals as part of the RRM (Radio Resource Management) configuration. The blacklist may be used to prevent the terminal device from reselecting to neighboring cells within a specific frequency and between frequencies. This functionality of this existing white and black can complement the power boost availability whitelist concept described herein.

  The embodiments described above have mainly focused on the method of operation according to embodiments of the present invention for idle mode terminal devices. However, when the terminal device is in connected mode, the corresponding principle can be applied, for example, to support the handover procedure.

  When the terminal device is in RRC connection mode, as a result, mobility is under the control of E-UTRAN, and with the support of the terminal device measurement, etc., the whitelist approach similar to that described above is different for different base stations. In order to guarantee the handover decision considering the information about the range that supports power boost (the blacklist can also work as usual) and actually improve the validity of the RRM measurement sent to the base station May be applied. As in the RRC idle mode, this prevents the terminal device from reporting unnecessary to base stations / cells that the terminal device can detect but are not in its whitelist and cannot support its coverage requirements. it can.

  FIG. 9 illustrates some operations of the terminal device 1403 and the base stations 1401A, B, and C of FIG. 6 for an exemplary embodiment of the present invention in which the terminal device is assumed to be in RRC connected mode at the base station 1401A. It is a ladder figure showing an aspect roughly.

  In the first step, the terminal device is activated after a pause period. In view of verifying whether it is appropriate to hand over to another base station according to the conventional LTE principle, the terminal device scans a synchronization signal broadcast by the base station. As described above, it is assumed that the terminal device is in the virtual coverage area of all three base stations 1401A, B, and C, for example, as in the configuration of FIG. Accordingly, as schematically represented in FIG. 9, the terminal device can receive primary (PSS) and secondary (SSS) signals from each of the base stations. In accordance with the principles described above, each base station that supports power boost does this by making a transmission (eg, signal repetition) associated with their synchronization signal, particularly over the transmission resources defined for this purpose. Configured as shown. This is schematically illustrated in FIG. 9 for base stations that support power boost (ie, base stations 1401A and 1401B) by labeling them as “PBA indications” in relation to their PSS / SSS signal representation. . A base station that does not support power boost (eg, base station 1401C) does not perform a transmission related to the synchronization signal with a given transmission resource, which means that power boost cannot actually be used. (As shown in FIG. 9, by labeling “PBA not shown” for the PSS / SSS signal from base station 1401C).

  Similar to the above-described embodiment, the terminal device 1403 is configured to search for a repetition of a synchronization signal on a transmission resource defined to indicate the availability of power boost, and such a synchronization signal is detected. In this case, the terminal device 1403 determines that the corresponding base station supports power boost. Therefore, the terminal device 1403 is not supported by the base station 1401C. Base stations 1401A and 1401B determine to support power boost. Accordingly, the terminal device 1403 reaches the stage of identifying that the base stations are in range and which of them support power boost.

  In the next two steps shown in FIG. 9, the terminal device 1403 defines which base station has the potential to provide optimal channel conditions (considering the availability of power boost) To do. This is based on the RSRP measurement and ranking process for each base station, taking into account the availability of power boost for each base station. These stages can be performed in much the same way as the corresponding steps in FIG.

  In the example of FIG. 7 (cell selection from RRC idle), the terminal device determines which base station it camps on from the cell ranking procedure. However, in the example of FIG. 9, the terminal device is already connected to the base station 1401A. Therefore, after the cell ranking stage shown in FIG. 9, the terminal apparatus transmits a measurement report related to RSRP measurement performed on the neighboring cell to the base station 1401A. In general, the procedure and format for sending this report can follow established practices for LTE type networks. However, in the present embodiment, a significant difference from the conventional scheme is that the measurement report transmitted from the terminal device 1403 to the base station 1401A is changed to consider the availability of power boost according to the above principle. Based on RSRP measurements (eg, by adding an offset based on the indicated power boost).

  When the base station 1401A where the terminal device 1403 camps on receives the measurement report, the base station may proceed as usual to determine whether to hand over the terminal device to another base station. That is, from the viewpoint of the base station, the handover procedure may be conventional. That is, the subsequent procedure in which a handover decision is made based on the modified RSRP (as opposed to the actual one) received from the terminal device 1403 is not important.

  In this example, the measurement report from the terminal device may be that the base station 1401B is associated with a better operating state for the terminal device 1403 or at least uses a power boost that it can support. It shows that. Therefore, as schematically shown in the next stage of FIG. 9, the base station 1401A determines that the terminal device is handed over to the base station 1401B. According to the established technology, as schematically shown in FIG. 9, the terminal device can switch to this syndicated mode at the base station 1401B, and in order to report when this is completed, the base station 1401A (handover source Cell), base station 1401B (handover destination cell), and terminal device 1403 exchange signals.

  In a variation of the method of FIG. 9, each base station may not have to convey to the terminal device an indication of the range in which they support power boost. Therefore, the terminal device may perform RSRP measurement and provide a measurement report according to conventional techniques. The base station to which the terminal device is RRC connected may then make a handover decision based on conventional RSRP measurements reported by the terminal device along with information about the range for which the neighboring base station supports power boost. it can. That is, the base station itself may be involved in modifying the RSRP measurement received from the terminal device in consideration of the power boost that is actually available in the neighboring cell. For example, the base station adds a power offset appropriate for RSRP measurements associated with other base stations based on information about the function that supports power boost received from other base stations on the X2 signal as described above. May be.

  While embodiments of the present invention have been described with reference to LTE mobile radio networks, it will be appreciated that the present invention can be applied to other forms of networks such as GSM, 3G / UMTS, CDMA2000, etc. . The term MTC terminal used in this specification can be replaced with user equipment (UE), a mobile communication device, a terminal device, and the like. Furthermore, although the term base station is used interchangeably with eNodeB, it should be understood that there is no functional difference between these network devices.

  Thus, a wireless communication system including a base station for communicating with a terminal device is described. One or more base stations can use the base station to provide enhanced transmit power compared to the transmit power on these transmission resources when the base station is not operating in power boost mode. Supports a power boost mode of operation where transmit power is concentrated in a subset of its available transmit resources. The base station defines a range in which one or more base stations in the wireless communication system support the power boost mode of operation, and conveys this indication to the terminal device. The terminal device receives the indication and considers which base station supports power boost and / or when power boost is supported during the cell attach procedure. Use the corresponding information to control.

  Thus, embodiments of the present invention allow the network operator to provide additional information that is conveyed to the terminal device regarding the suitability of different cells in order to meet the requirements of the terminal device. This can support reducing unnecessary connection attempts by the terminal device. As a result, power consumption of the terminal can be reduced, and generally fewer terminal devices attempt to acquire a specific cell, so that uplink interference on the PRACH can be reduced. The configurable characteristics of an approach according to embodiments of the present invention are, for example, between cell efficiency and coverage, rather than always tolerate some sacrifice and both such inefficient resources and power usage. To provide balance, it means that the operator can enable coverage extension (power boost) only for a selected time of day. In the RRC idle state, when the terminal device finally enters the RRC connection state, the terminal device may avoid selecting to camp on a cell that cannot support power boost. Therefore, the terminal device can avoid such power consumption of listening for paging and SI on the cell. Such cells usually do not need to be stored in a limited space for a list of candidate cells for cell reselection.

  Embodiments of the present invention also allow the terminal equipment (UE) to sleep for a relatively long period of time, so that the network can efficiently provide coverage (since power boost is available). It can be activated only when the network indicates, and again, it can offer the possibility of a significant reduction in power consumption. These results may be particularly relevant to some MTC scenarios where the terminal device may not be connectable and may have limited battery life.

  Embodiments of the present disclosure can be applied to a wireless communication system that supports a virtual carrier operation mode. For example, a virtual carrier that can be used to communicate at least some information with a particular type of terminal device, such as a low-function machine type communication terminal device, is an entire transmission resource grid associated with the host carrier. Represents a limited subset of downlink transmission resources within. Thus, downlink communication is performed by the base station using a radio interface that spans the system frequency bandwidth, and at least some communication from the base station within a limited subset of transmission resources selected from within the system frequency band. The virtual carrier operation may be summarized as an approach in a wireless communication system in which a terminal is configured to receive and includes a limited bandwidth downlink channel having a channel bandwidth smaller than the system frequency bandwidth. it can.

  The primary driver for a certain type of terminal device, such as an MTC device, is desired to be relatively simple and inexpensive for such a device. For example, typically the type of function performed by an MTC type terminal (eg, simple data collection and relatively small amount of report / reception) is performed, eg, compared to a smartphone that supports video streaming Therefore, no particularly complicated processing is required. However, third and fourth generation mobile communication networks are generally wide on radio interfaces that require more complex and expensive radio transceivers and decoders to use and implement advanced data modulation techniques. Support bandwidth usage. Since smartphones typically require powerful processors to perform common smartphone-type functions, it is usually justified to include such complex elements within the smartphone. However, as noted above, there is a current desire to use a relatively inexpensive and less complex device, even though it can communicate using an LTE type network.

  With this in mind, for example, described in GB2487906 (7), GB2487908 (8), GB2487780 (9), GB2488513 (10), GB2487757 (11), GB2487909 (12), GB2487907 (13) and GB2487782 (14) As has been proposed, the concept of so-called “virtual carrier” that operates within the bandwidth of the “host carrier” has been proposed. One basic virtual carrier concept principle is that a carrier frequency sub-region (a subset of frequency resources) within a host carrier with a wider bandwidth (a wider range of frequency resources) Being configured to be used as an independent carrier for at least some types of communications. For example, the terminal device may be configured to receive at least some communications from the base station within a limited subset of transmission resources selected from within the system frequency band, thereby limiting the transmission resources. The subset includes downlink channels that have a channel bandwidth that is less than the system frequency bandwidth.

  As described in references (7) to (14), in some virtual carrier implementations, all downlink control signals and user plane data for terminal devices using virtual carriers are associated with virtual carriers. It may be carried within a subset of frequency resources. A terminal device operating on a virtual carrier needs to recognize limited frequency resources, receive only a corresponding subset of transmission resources, and decode in order to receive data from the base station. One advantage of this approach is that it provides a carrier for use by low-function terminal devices that can operate over a relatively narrow bandwidth. This allows devices to communicate over LTE type networks without the need for devices to support full bandwidth operation. Since the complexity of these functions is generally related to the bandwidth of the received signal, it is configured to operate on a virtual carrier by reducing the bandwidth of the signal that needs to be decoded. The initial processing requirements of the device (eg, FFT, channel estimation, buffering subframes, etc.) are reduced.

  Other virtual carrier approaches to reduce the complexity required for devices configured to communicate over LTE type networks are proposed in GB2497743 (15) and GB2497742 (16). These documents propose a method for communicating data between a base station and a low function terminal device, so that the physical layer control information for the low function terminal device is stored in the entire host carrier frequency band. Transmitted from the base station using subcarriers selected from (such as for a conventional LTE terminal). However, the upper layer data (eg, user plane data) for the low function terminal device is in the set of subcarriers including the system frequency band, and only the subcarriers selected from the limited subset of narrower carriers are included. Sent using. Thus, this means that user plane data for a particular terminal may be limited to a subset of frequency resources (ie, virtual carriers supported within the transmission resources of the host carrier), while the control signal reduces the total bandwidth of the host carrier. It is an approach that is transported using. The terminal device recognizes the limited frequency resource, and requires buffering and processing of only the data in the frequency resource during the period when the upper layer data is transmitted. During the period in which the physical layer control information is transmitted, the terminal device buffers and processes the frequency band of the entire system. Thus, the low function terminal device may be embedded in a network where physical layer control information is transmitted over a wide frequency range, but with sufficient memory to process a narrower range of frequency resources for higher layer data. It only needs to have processing power. This approach is often referred to as a “T-type” assignment because the region of the downlink time-frequency resource grid used by low-function terminals typically includes a T-shape in some cases.

  In this way, the concept of virtual carriers can be such that, for example, terminal devices with reduced functionality in terms of their transmit / receive bandwidth and / or processing capability are supported in LTE type networks.

  In a wireless communication system, it is expected that a terminal device that also depends on the power boost operation mode may depend on the virtual carrier operation mode. Also, in certain wireless communication systems, it is expected that some base stations may support a virtual carrier mode of operation while some base stations may not support a virtual carrier mode of operation. Accordingly, in some exemplary embodiments of the present disclosure, it may be useful for a terminal device to recognize whether a base station to which the terminal device is to connect / attach supports a virtual carrier operation mode. . This is useful for avoiding a terminal device that relies on virtual carrier operation from attempting to attach to a base station that does not support the virtual carrier operation mode. Many aspects of this problem are very similar to the problem described above, which helps to avoid a terminal device that relies on power boost operation trying to attach to a base station that does not support the power boost operation mode. ing. In this regard, it will be appreciated that many of the comments above associated with power boost operations apply as well in the context of virtual carrier operations.

  Thus, certain embodiments of the present invention have a virtual carrier mode (eg, whether / when the base station supports virtual carrier operation) in terms of reducing wasted camp-on attempts. A scheme for providing information related to the function of the base station operating in the terminal apparatus may be targeted. Accordingly, the terminal apparatus can perform the base of the wireless communication system based on information received from the one or more base stations regarding the range in which the one or more base stations in the wireless communication system support the virtual carrier operation mode Station acquisition may be controlled. In view of the functions of different base stations regarding the virtual carrier mode of operation, the terminal device may be able to control the acquisition of the base station according to embodiments of the present disclosure more efficiently. For example, a terminal device that relies on virtual carrier operation may avoid attempting to attach to a base station that does not support virtual carrier operation, and / or virtual carrier operation may The connection to the base station may be delayed until a later time when it is available.

  As described above, according to some embodiments of the present disclosure, the base station may be configured to provide the terminal device with information regarding the range in which the neighboring base station supports power boost. Similarly, according to another particular embodiment, the base station is configured to additionally or alternatively provide the terminal device with information about the range in which one or more neighboring base stations support virtual carrier operation. May be.

  As described above, if the terminal device in idle mode is already camping on the initial cell / base station, for example, the quality of the signal associated with the initial cell is degraded and / or the terminal device changes location (Ie due to mobility), it may be appropriate to consider moving to another cell. The terminal apparatus according to the embodiment of the present disclosure may perform the cell reselection procedure in consideration of a range in which different base stations provide virtual carrier operations. In response to cell reselection, the terminal device has already connected to the system information because it is camping on the base station of the network. Thus, according to some embodiments of the present invention, the information carried in the system information is used by different base stations in the network to support virtual carriers in order to assist the terminal equipment to control the acquisition of those base stations. It may be used to provide an indication of the range that supports the operation. This type of approach can be provided in combination with a signaling approach (whether implicit or via system information) to convey information regarding the capabilities of base stations that support power boost, as described above, Alternatively, it may be provided separately. That is, the approach for carrying the power boost indication described herein (ie, the indication of the range in which the base station supports the power boost mode of operation) is similarly the indication of the virtual carrier (ie, the base station is virtual). Range indication supporting carrier operating mode), which may be done in combination with the delivery of any power boost indication, or may be separate, May be independent. In practice, the approach for carrying an indication of the range in which one or more base stations support the virtual carrier mode of operation as described herein is conversely a wireless communication system that does not support power boost operation. Can be implemented.

Thus, a base station supports virtual carrier operation in a wireless communication system according to some embodiments, and points such as frequency resources used for virtual carrier operation, time during which virtual carrier operation is available, etc. Thus, the concept of a list of potential virtual carrier behavior characteristics provided by the base station may be introduced. This is sometimes referred to as a whitelist for virtual carrier availability for convenience. For example, the list may be broadcast by the base station in association with system information normally received by a terminal device attached to the base station. Accordingly, a terminal device that is already connected to the base station can be easily provided with information regarding the range in which other base stations support virtual carrier operation in the network. This information can assist in determining whether the terminal device moves to another base station by considering whether the other base station can support the terminal device in the virtual carrier mode of operation. The following table represents an example of a virtual carrier availability whitelist that links a communication cell identifier (PCI) to an indication of whether each cell supports virtual carrier operation.

  Each base station may be configured to maintain a white list for communication with their connected terminal devices. A list on their support for virtual carrier operation can be (semi-) dynamically based on communication between base stations, for example using the X2 interface between base stations with additional information elements newly defined. It may be held. For example, if a base station needs to change support for virtual carrier operation, individual base stations may communicate with neighboring base stations using X2 signaling. Alternatively, the list may be (semi) static based on the network settings selected by the operator. Therefore, if the terminal device in idle mode measures the RSRP / RSRQ of cell ID 432, the terminal device is associated with a good channel condition, but nevertheless it does (currently) perform virtual carrier operation. Since it is not supported, it may be determined that it should be avoided.

  Thus, according to some embodiments, a serving cell to which a terminal device is already connected may provide a VC (virtual carrier) indication related to a neighboring cell. If the terminal device is connected to the serving cell (probably, but not necessarily, after determining to connect in a way that takes into account the power boost availability indication as described above), the RRC configuration signal Used to carry VC indications associated with base stations / cells.

  As described above in the context of carrying power boost information to neighboring cells, neighboring cell VC information is also provided to idle terminal devices by including relevant information in the system information (SI) broadcast. The terminal device in the idle mode periodically confirms the change in SI by confirming the subframe configuration pattern for the paging PDCCH indicating the PDSCH resource in which the SI is held in the subframe. This provides a mechanism for idle mode terminal devices that receive explicit signals regarding the function of one or more base stations with respect to virtual carrier operation.

  A simpler version of the VC whitelist may indicate a cell ID that can simply support virtual carrier operation (or conversely, which cell ID cannot support virtual carrier operation).

  Further particular preferred embodiments of the invention are set out in the accompanying independent and dependent claims. As will be appreciated, the features of the dependent claims may be combined with the features of the independent claims in combinations other than those explicitly recited in the claims.

<Reference>
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(5) ETSI TS 123 122 V11.4.0 (2013-01) / 3GPP TS 23.122 Version 11.4.0 Release 11
(6) ETSI TS 136 101 V11.3.0 (2013-02) / 3GPP TS 36.101 Version 11.3.0 Release 11
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Claims (10)

A limited bandwidth downlink in which at least some downlink communication is performed using a limited subset of transmission resources selected from within the system frequency band and has a channel bandwidth that is narrower than the system frequency band A method for operating a base station in a wireless communication system comprising one or more base stations supporting a virtual carrier mode of operation, including a channel, comprising:
In order to define a range in which one or more base stations support the virtual carrier operation mode, and to control acquisition of base stations of the wireless communication system performed by a terminal device, one or more base stations In order for the terminal device to consider the range indication that supports the virtual carrier operation mode, the wireless communication system may indicate the range indication that one or more base stations support the virtual carrier operation mode. Transporting to a terminal device operating within,
The range indication relates to the range in which at least one other base station supports the virtual carrier mode of operation within the wireless communication system;
The method wherein the range indication indicates when the at least one other base station supports the virtual carrier mode of operation.   The method of claim 1, wherein the terminal device is connected to the base station and not connected to the at least one other base station.   3. The method of claim 1, further comprising: receiving from the at least one additional base station an indication of the range in which the at least one additional base station supports the virtual carrier mode of operation within the wireless communication system. the method of.   The method according to one of claims 1 to 3, wherein the indication of the range in which one or more base stations support the virtual carrier mode of operation is conveyed to the terminal device using an explicit signal.   The method of claim 4, wherein the explicit signal comprises a system information signal. A limited bandwidth downlink in which at least some downlink communication is performed using a limited subset of transmission resources selected from within the system frequency band and has a channel bandwidth that is narrower than the system frequency band A base station that operates in a wireless communication system comprising one or more base stations that support a virtual carrier operating mode, including a channel, wherein the one or more base stations support the virtual carrier operating mode And the terminal device considers the range indication that one or more base stations support the virtual carrier mode of operation in order to control the base station acquisition of the wireless communication system performed by the terminal device The range in which one or more base stations support the virtual carrier mode of operation. Consists instructions to to carry the terminal device operating within the wireless communication system,
The range indication relates to the range in which at least one other base station supports the virtual carrier mode of operation within the wireless communication system;
The range indication indicates when the at least one other base station supports the virtual carrier mode of operation.   The base station according to claim 6, wherein the terminal device is connected to the base station and is not connected to the at least one other base station.   Further, in the wireless communication system, the at least one further base station is configured to receive from the at least one further base station an indication of the range that supports the virtual carrier mode of operation. Base station.   9. The indication of the range in which one or more base stations support the virtual carrier mode of operation is configured to be conveyed to the terminal device using an explicit signal. Any base station. The base station of claim 9, wherein the explicit signal comprises a system information signal.

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